The high-pressure behaviour of meyerhofferite [ideally Ca2B6O6(OH)10ꞏ2(H2O), with a ~6.63 Å, b ~8.34 Å, c ~6.47 Å, α = 90.8°, β = 102°, γ=86.8°, Sp. Gr. P1 ], a B-bearing raw material (with B2O3 46 wt%) and a potential B-rich aggregate, has been studied by single-crystal synchrotron X-ray diffraction up to 9 GPa, under hydrostatic conditions. Meyerhofferite undergoes a first-order phase transition to meyerhofferite-II, likely iso-symmetric, bracketed between 3.05 and 3.48 GPa, with a spectacular unit-cell volume discontinuity (i.e., V~ 30 Å 3 ). The isothermal bulk modulus (KV0= -1 P0,T0, where P0,T0 is the volume compressibility coefficient) of meyerhofferite was found to be KV0 =31.6(5) GPa, and a marked anisotropic compressional pattern, with K(a)0 : K(b)0 : K(c)0 ~1.5:1:3, was observed. The bulk modulus of meyerhofferite-II increases to 55(2) GPa and, differently to the majority of the borates studied at high pressure so far, the anisotropic compressional pattern of meyerhofferite decreases markedly in the high-pressure form. The P-induced deformation mechanisms controlling, at the atomic scale, the bulk compression of meyerhofferite are here described. Considerations about the use of meyerhofferite as a potential B-based aggregate in concretes, mortars or resins, are provided.